Skip to main content
SpringerLink
Log in

A computational model of vertical signal propagation in the primary visual cortex

  • Published:
Biological Cybernetics Aims and scope Submit manuscript

Abstract

A computational model of the flow of activity in a vertically organized slab of cat primary visual cortex (area 17) has been developed. The membrane potential of each cell in the model, as a function of time, is given by the solution of a system of first order, coupled, non-linear differential equations. When firing threshold is exceeded, an action potential waveform is “pasted” in. The behavior of the model following a brief simulated stimulus to afferents from the dorsal lateral geniculate nucleus (dLGN) is explored. Excitatory and inhibitory post-synaptic potential (E and IPSP) latencies, as a function of cortical depth, were generated by the model. These data were compared with the experimental literature. In general, good agreement was found for EPSPs. Many disynaptic inhibitory inputs were found to be “masked” by the firing of action potentials in the model. To our knowledge this phenomenon has not been reported in the experimental literature. The model demonstrates that whether a cell exhibits disynaptic or polysynaptic PSP latencies is not a fixed consequence of anatomical connectivity, but rather, can be influenced by connection strengths, and may be influenced by the ongoing pattern of activity in the cortex.

This is a preview of subscription content, log in via an institution to check access.

Access this article

Log in via an institution

Price excludes VAT (USA)
Tax calculation will be finalised during checkout.

Instant access to the full article PDF.

Institutional subscriptions

Similar content being viewed by others

References

  • Aidely DJ (1978) The physiology of excitable cells. Cambridge Unversity Press, Cambridge

    Google Scholar 

  • Berry MS, Pentreath VW (1976) Criteria for distinguishing between monosynaptic and polysynaptic transmission. Brain Res 105:1–20

    Google Scholar 

  • Brown TH, Johnston D (1983) Voltage-clamp analysis of mossy fiber synaptic input to hippocampal neurons. J Neurophysiol 50(2):487–507

    Google Scholar 

  • Bullier J, Henry GH (1979) Ordinal position of neurons in cat striate cortex. J Neurophysiol 42(5):1251–1263

    Google Scholar 

  • Bush PC, Douglas RJ (1991) Synchronization of bursting action potential discharge in a model network of neocortical neurons. Neural Computat 3:19–30

    Google Scholar 

  • Chagnac-Amitai Y, Connors BW (1989) Horizontal spread of synchronized activity in neorcortex and its control by GABA mediated inhibition. J Neurophysiol 42(5):1271–1281

    Google Scholar 

  • Connors BW, Butnick MJ, Prince DA (1982) Electrophysiological properties of neocortical neurons in vitro. J Neurophysiol 48:1302–1320

    Google Scholar 

  • Connors BW, Malenka RC, Solva IR (1988) Two inhibitory postsynaptic potentials, and GABAa and GABAb receptor-mediated repsonses in neocortex of rat and cat. J Physiol 406:443–468

    Google Scholar 

  • Connors BW, Gutnick MJ (1990) Intrinsic firing patterns of diverse neocortical neurons. Trends Neurosci 13(3):99–104

    Google Scholar 

  • Douglas RJ, Martin KAC, Whitteridge D (1989) A canonical microcircuit for neocortex. Neural Computat 1:480–488

    Google Scholar 

  • Douglas RJ, Martin KAC (1990) Neocortex In: Shepherd GM (ed) The synaptic organization of the brain, 3rd Edn. Oxford University Press, New York Oxford, pp 389–438

    Google Scholar 

  • Ferster D, Lindström S (1983) An intracellular analysis of geniculocortical connectivity in area 17 of the cat. J Physiol 342:181–215

    Google Scholar 

  • Freund TF, Martin KAC, Smith AD, Somogyi P (1983) Glutamate decarboxylase-immunoreactive terminals of Golgi-impregnated axoaxonix cells and of presumed basket cells in synaptic contact with pyramidal neurons of cat's visual cortex. J Comp Neurol 221:263–278

    Google Scholar 

  • Gray CM, Singer W (1989) Stimulus-specific neuronal oscillations in orientation columns of cat visual cortex. Proc Natl Acad Sci USA 86:1698–1702.

    Google Scholar 

  • Gray CM, König P, Engel AK, Singer W (1989) Oscillatory responses in cat visual cortex exhibit inter-columnar synchronization which reflects global stimulus properties, nature 338:335–337.

    Google Scholar 

  • Gremillion M, Mandell A, Travis B (1987) Neural nets with complex structure: a model of the visual system. Proc Int Conf Neural Networks (IEEE) 4:235–246

    Google Scholar 

  • Hablitz JJ, Thalmann RH (1987) Conductance changes underlying a late synaptic hyperpolarization in hippocampal CA3 neurons. J Neurophysiol 58(1):160–179

    Google Scholar 

  • Henry GH, Harvey AR, Lund JS (1979) On the afferent connections and laminar distribution of cells in the cat striate cortex. J Comp Neurol 187:725–744

    Google Scholar 

  • Krone G, Mallot H, Palm G, Schüz A (1986) Spatiotemporal receptive fields: a dynamical model derived from cortical architectonics. Proc R Soc Lond B 226:421–444

    Google Scholar 

  • MacDermott AB, Dale N (1987) Receptors, ion channels and synaptic potentials underlying the integrative actions of excitatory amino acids. Trends Neurosci 10(7):280–293

    Google Scholar 

  • McCormick DA, Connors BW, Lighthall JW, and Prince DA (1985) Comparative electrophysiology of pyramidal and sparsely spiny stellate neurons of the neocortex. J Neurophysiol 54(4):782–806

    Google Scholar 

  • McCormick DA (1990) Membrane properties and neurotransmitter actions. In: Shepherd GM (ed), The synaptic organization of the brain. Oxford Universidy Press, New York Oxford, pp 32–67

    Google Scholar 

  • Miles R, Wong RKS (1986) Excitatory synaptic interactions between CA3 neurones in guinea-pig hippocampus. J Physiol 373:397–418

    Google Scholar 

  • Miles R, Traub RD, Wong RKS (1988) Spread of synchronous firing in longitudinal slices from the CA3 region of the hippocampus. J Neurophys 60(4):1481–1496

    Google Scholar 

  • Miles R (1990a) Variations in strength of inhibitory synapses in the CA3 region of guinea-pig hippocampus in vitro. J Physiol 431:659–676

    Google Scholar 

  • Miles R (1990b) Synaptic excitation of inhibitory cells by single CA3 hippocampal pyramidal cells of the guinea-pig in vitro. J Physiol 428:61–77

    Google Scholar 

  • Morrison JH, Magistretti PJ, Benoit R, and Bloom FE (1984) The distribution and morphological characteristics of intracortical VIP-positive cell: an immunohistochemical analysis. Brain Res 292:269–282

    Google Scholar 

  • Peters A, Proskauer CC (1980) Synaptic relationship between a multipolar stellate cell and a pyramidal neuron in rat visual cortex: a combined Golgi-electron microscope study. J Neurocytol 9:163–183

    Google Scholar 

  • Peters A, Kimerer LM (1981) Bipolar neurons in the rat visual cortex: a combined Golgi-electron microscope study. J Neurocytol 10:921–946

    Google Scholar 

  • Shepherd GM (1979) The synaptic organization of the brain. Oxford University Press, New York

    Google Scholar 

  • Stone J, Dreher B (1982) Parallel processing of information in the visual pathway. Trends Neurosci 5:441–446

    Google Scholar 

  • Somogyi P, Cowey A (1981) Combined golgi and electron microscopic study on the synapses formed by double bouquet cells in the visual cortex of the cat and monkey. J Comp Neurol 195:547–566

    Google Scholar 

  • Swadlow HA (1974) Systemic variations in the conduction velocity of slowly conducting axons in rabbit corpus callosum. Exp Neurol 43:445–451

    Google Scholar 

  • Swadlow HA, Weyand TG, Waxman SG (1978) The cells of origin of the corpus callosum in rabbit visual cortex. Exp Neurol 43:445–451

    Google Scholar 

  • Toyama K, Mastunami K, Ohno T, Tokashiki S (1974) An intracellular study of neuronal organization in the visual cortex. Exp Brain Res 21:45–66

    Google Scholar 

  • Thomas E, Patton P, Wyatt RE (1991) A computational model of the vertical anatomical organization of primary visual cortex. Biol Cybern 65:189–202

    Google Scholar 

  • Wehmeier U, Dong D, Koch C, Van Essen D (1989) Modeling the mammalian visual system. In: Koch C, Segev I (eds) Methods in Neuronal Modeling. MIT Press, Cambridge, pp 335–361

    Google Scholar 

  • Wilson HR, Cowan JD (1973) A mathematical theory of the functional dynamics of cortical and thalamic nervous tissue. Kybernetik 13:55–80

    Google Scholar 

  • Wyatt RE, Driver J (1991) Computational Brain Dynamics, Cray Channels, Fall 1991 issue

Download references

Author information

Authors and Affiliations

  1. Division of Neural Systems, Memory, and Aging, 384 Life Sciences North Building, Arizona Research Laboratories, 85724, Tucson, AZ, USA

    Paul Patton

  2. Department of Chemistry and Institute of Theoretical Chemistry, University of Texas, 78712, Austin, TX, USA

    Elizabeth Thomas & Robert E. Wyatt

Authors
  1. Paul Patton
    View author publications

    You can also search for this author in PubMed Google Scholar

  2. Elizabeth Thomas
    View author publications

    You can also search for this author in PubMed Google Scholar

  3. Robert E. Wyatt
    View author publications

    You can also search for this author in PubMed Google Scholar

Additional information

Supported by a grant from Cray Research Inc.

Rights and permissions

Reprints and permissions

About this article

Cite this article

Patton, P., Thomas, E. & Wyatt, R.E. A computational model of vertical signal propagation in the primary visual cortex. Biol. Cybern. 68, 43–52 (1992). https://doi.org/10.1007/BF00203136

Download citation

  • Received:

  • Accepted:

  • Issue Date:

  • DOI: https://doi.org/10.1007/BF00203136

Keywords

Search

Navigation